Contributions of diffuse and directed flow in turbid media to absolute measurements of tissue perfusion and oxygen consumption using laser speckle and spatial frequency domain imaging

Abstract Introduction While visual assessment is the standard for burn severity evaluation, new technologies are attempting to increase objectivity. Burn depth assessment accuracy improves over time as the appearance changes, but earlier diagnosis potentially leads to prompt treatment and shorter recovery. Laser Speckle Imaging (LSI), FDA approved for grading burns, is typically done 72hrs after injury. Spatial Frequency Domain Imaging (SFDI), a novel technology only tested in animal burn models, uses multiple wavelengths of patterned light to quantify tissue absorption (hemodynamics) and scattering (structure). SFDI has shown the potential to differentiate burns as early as 24hrs postburn by measuring scattering (µs’) changes due to collagen damage. Here, we examine SFDI burn severity assessment in clinical patients, and compare against LSI and clinical assessment. Methods 5 burn cases were imaged with LSI and SFDI approximately 24 and 72hrs postburn. The clinician was blinded to imaging results and made diagnoses on their standard of care. Results One patient received no surgical intervention, one received excision and xenograft, and two received excision and autograft. An autograft was recommended for one patient, but not performed due to preexisting conditions. SFDI measurements at 24hrs showed low µs’ values in regions that eventually required autografts, and high µs’ in burns that did not. While clinical decisions were made no earlier than 72hrs postburn, µs’ maps at 24hrs postburn were able to illustrate severity in these regions. In 2 of 3 autograft cases, LSI was unable to determine the severity until 72hrs postburn. Conclusions Here, we compared SFDI to LSI in a clinical setting to quantify burn wound severity. Similar to animal models, SFDI was demonstrated to accurately characterize severity earlier than the perfusion-based LSI. This is likely due to sensitivity of µs’ measured by SFDI to the structural changes in damaged collagen (i.e., zone of coagulation) that occur immediately postburn.

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Halftone spatial frequency domain imaging enables kilohertz high-speed label-free non-contact quantitative mapping of optical properties for strongly turbid media

Light Science & Applications ◽

10.1038/s41377-021-00681-9 ◽

2021 ◽

Vol 10 (1) ◽

Author(s):

Yanyu Zhao ◽

Bowen Song ◽

Ming Wang ◽

Yang Zhao ◽

Yubo Fan

Keyword(s):

Optical Properties ◽

Spatial Frequency ◽

Frequency Domain ◽

High Speed ◽

Turbid Media ◽

Wide Field ◽

Label Free ◽

Spatial Frequency Domain Imaging ◽

Spatial Frequency Domain

AbstractThe ability to quantify optical properties (i.e., absorption and scattering) of strongly turbid media has major implications on the characterization of biological tissues, fluid fields, and many others. However, there are few methods that can provide wide-field quantification of optical properties, and none is able to perform quantitative optical property imaging with high-speed (e.g., kilohertz) capabilities. Here we develop a new imaging modality termed halftone spatial frequency domain imaging (halftone-SFDI), which is approximately two orders of magnitude faster than the state-of-the-art, and provides kilohertz high-speed, label-free, non-contact, wide-field quantification for the optical properties of strongly turbid media. This method utilizes halftone binary patterned illumination to target the spatial frequency response of turbid media, which is then mapped to optical properties using model-based analysis. We validate the halftone-SFDI on an array of phantoms with a wide range of optical properties as well as in vivo human tissue. We demonstrate with an in vivo rat brain cortex imaging study, and show that halftone-SFDI can longitudinally monitor the absolute concentration as well as spatial distribution of functional chromophores in tissue. We also show that halftone-SFDI can spatially map dual-wavelength optical properties of a highly dynamic flow field at kilohertz speed. Together, these results highlight the potential of halftone-SFDI to enable new capabilities in fundamental research and translational studies including brain science and fluid dynamics.

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